Method and device for monitoring an optical amplifier, in particular, an optical fiber amplifier

ABSTRACT

The invention relates to a method for monitoring an optical amplifier, in particular, an optical fiber amplifier, which has an optical input port ( 3 ) and an optical output port ( 5 ), between which an optical path ( 7 ) extends, in which an optical amplification means ( 9 ) is arranged, which has at least one pumping source ( 19 ), whose optical power (P pump ) is supplied via a coupling unit ( 11 ) to optical path ( 7 ), wherein the optical input signal power (P in ) supplied to input port ( 3 ) of optical amplifier ( 1 ) and/or the optical output signal power (P out ) emitted at output port ( 5 ) of optical amplifier ( 1 ) is detected and wherein the gain (G) of optical amplifier ( 1 ) is to be controlled or regulated to a predetermined nominal value. According to the invention, the optical pumping power (P pump ) is presumed to be approximately directly proportional to the electrical pumping current (I pump ), the time-variant proportionality constant subject to a degradation over time being designated with α(t). Additionally, the functional dependence of the optical pumping power (P pump ) on the optical input signal power (P in ) and/or the optical output signal power (P out ) is determined at least for the predetermined nominal value of the gain (G), the current value (P pump,1 ) for the optical pumping power being determined by means of this functional dependence as well as a currently detected value (P in,1 ) for the optical input signal power or a currently detected value (P out,1 ) for the output signal power. With the thus-determined value (P pump,1 ) for the current optical pumping power and a currently detected first value (I pump,1 ) for the pumping current, the current value for the proportionality constant (α(t 1 )) is determined from the proportionality relationship. The maximum possible value (P pump,max ) for the pumping power is determined by means of the proportionality relationship from the maximum permissible value (I pump,max ) for the pumping current and the currently valid value (α(t 1 )). Thereby, using the maximum possible value (P pump,max ) for the pumping power, the maximum value (P in,max ) for the optical input signal power and/or the maximum value for the optical output signal power (P out,max ) is determined from the inverse functional dependence of the pumping current on the optical input signal power and/or the optical output signal power.

The invention relates to a method for monitoring an optical amplifier with the characteristics of the preamble of Claim 1. The invention further relates to a device for performing this method according to the characteristics of the preamble of Claim 12.

Optical amplifiers such as fiber amplifiers using an erbium-doped fiber (known as erbium-doped fiber amplifiers (EDFA)) are used in optical transmission systems in order to amplify an optical payload signal that has been so severely attenuated after passing through a correspondingly long transmission path that an amplification of the signal is necessary. The direct amplification of the optical signal can be performed in an optical amplifier without the necessity of first performing an optoelectrical conversion and then an electrooptical conversion of the signal after signal amplification, as is the case for electrical amplification of the optical signal. The pumping power required in an optical amplifier is usually generated by means of a pump source having a laser diode, wherein the center wavelength of this pumping laser diode lies, for instance, in the range of 980 nm or in the range of 1480 nm. The pumping power is coupled by means of a coupler into the transmission path between the input port and the output port of the optical amplifier in the direction towards the optical amplification medium, for instance, an erbium-doped pumping fiber. The pumping power is absorbed by the erbium atoms; the optical signal to be amplified, which likewise passes through the pumping fiber, excites the erbium atoms, which have been excited to an elevated energy level, to produce a stimulated emission. The light generated in this manner thus has substantially the same frequency and the same phase as the optical payload signal to be amplified, which is thereby amplified in a purely optical manner. The optical gain G, which is defined as the ratio of the power of the amplified optical signal P_(out) available at the output port divided by the optical power P_(in) supplied to the input port, displays among other things a dependency on the degree of erbium doping and on the optical pumping power. The higher the pumping power P_(pump), the greater is the optical gain G.

It must be taken into account, however, that in order to amplify an optical input signal P_(in) of high power, a larger pumping power is also necessary in order to obtain the same gain G. The pumping power P_(pump) generated by the pumping laser diode is directly proportional, to a good approximation, to the electrical pumping current I_(pump) flowing through the pumping laser diode, i.e.:

P _(pump) =α·I _(pump)

where α designates the proportionality constant. It must naturally be taken into account that this relationship does not apply to very small pumping currents. For the range of optical pumping power P_(pump) that is of interest, however, this relation represents a good approximation.

Since a part of the electrical power supplied to the pumping laser diode is converted into thermal loss power, the pumping current is limited to a maximum value I_(pump,max). If this threshold for the pumping current is exceeded, the pumping laser diode is destroyed. Thus, the maximum possible optical pumping power is also limited to a maximum value P_(pump,max).

In an optical amplifier, the pumping power P_(pump) is typically regulated as a function of the power of the optical signal P_(in) to be amplified and of the power of the optical output signal such that a predetermined value for the gain G is obtained. If the input optical signal power P_(in) supplied to the input port of the amplifier is increased, for example because additional optical channels are added to an optical wavelength division multiplex transmission system, then the required optical pumping power P_(pump) and thus the pumping current I_(pump) must also be raised in order to keep the optical gain G at the desired value.

It must be taken into account in this regard that the pumping laser in particular is subject to aging effects, which are summarized under the term degradation. In other words, the pumping current I_(pump) must be increased with increasing aging of a pumping laser diode in order to keep the optical pumping power P_(pump) at a constant value. This circumstance is taken into account in the aforementioned proportionality relationship by introducing a time variance of the proportionality constant α(t). This situation is evident from the schematic representation in FIG. 2. This representation shows the aging effect of a pumping laser diode, which has the steepest correlation between the parameters I_(pump) and P_(pump) at a time t₀, and the corresponding correlation between these parameters at a later time t₂ has the lowest slope. In other words, α(t) decreases over time.

If the degradation of the pumping laser diode increases over time to such an extent that the pumping current has reached the maximum value I_(pump,max) and can no longer be increased, in order to avoid a destruction of the pumping laser diode, then the gain G of the amplifier is reduced, whereby the performance of the optical transmission system in question is worsened. With typical well-known optical amplifiers for optical transmission paths, an alarm signal is therefore generated when the maximum value I_(pump,max) for the pumping current, or a slightly lower value that guarantees a certain margin of safety, has been reached. For optical transmission systems in which an optical amplifier is initially operated well below the maximum permissible pumping current I_(pump,max), no alarm is issued, even if the pumping laser diode has already aged considerably, but a pumping current I_(pump)<I_(pump,max) still suffices to achieve the predetermined gain G.

However, if the optical transmission system and the optical amplifier were designed from the start for the amplification of larger input powers at the input of the optical amplifier, then it can occur that after a certain aging time, the maximum possible pumping power P_(pump,max) of the pumping laser diode is no longer sufficient to maintain the predetermined value G of the gain within the original specification if there is an increase of the optical input power P_(in) supplied to the amplifier. This can occur, for instance, in a wavelength division multiplex transmission system if additional channels are added after a certain aging time. Since the maximum possible pumping power P_(pump,max) no longer suffices, even the originally present channels are impaired. This is not acceptable, however.

Beginning from this state of the art, the invention is therefore based on the problem of creating a method for monitoring an optical amplifier which assures that an intended increase of the input power supplied to the amplifier does not lead to a reduction of the value for the optical gain G. A further problem underlying the invention is to create a device for performing the method.

The invention solves these problems with the characteristics of Claims 1 and 12, respectively.

The invention starts from the recognition that the connection between the pumping power P_(pump) that is necessary for the amplification of an input signal with input signal power P_(in) with a predetermined gain G is not subject to any substantial degradation and therefore need be determined only one time for the optical amplifier in question (or also for a given type of an optical amplifier if a sufficiently small scattering of the characteristics of the individual components can be guaranteed), and can be stored, for instance. Instead of or in addition to the parameter P_(in), it is of course possible for the output signal power P_(out) to be included in this correlation, since the two parameters are directly connected via the gain G.

Thus, for a given (current) input signal power P_(in,1) and/or a given (current) output signal power P_(out,1), the required pumping power P_(pump,1) can be ascertained from this correlation that is determined only once.

Under the assumption of a direct proportionality between the optical pumping power P_(pump) and the electric pumping current I_(pump), the time-variant proportionality constant α(t₁) effective at the respective time t₁ can then be determined from these two parameters. The instantaneous pumping current I_(pump,1) can also be detected in an ordinary manner by direct or indirect measurement or can be supplied as an analog or digital value by the drive unit of the pumping source.

Using the thus-determined value for the currently valid proportionality constant α(t₁), it is then possible, with the likewise known, maximally permissible value I_(pump,max), to calculate the maximum possible pumping power P_(pump,max). Using the known connection between the pumping current P_(pump) and the optical input signal power P_(in), or the optical output signal power P_(out) the associated maximum value for the optical input signal power P_(in,max), or the maximum value for the optical output signal power P_(out,max), can be determined by means of the value for the maximum pumping power P_(pump,max) determined in the manner above. If the connection between the pumping power and the optical input signal power or the optical output signal power is known only as a functional dependency in one direction, then an inversion of the respective dependence may be necessary for this purpose.

It can thus be determined for an intended application of a desired optical power P_(in) to the input port of the amplifier whether, under the assumption that a predetermined value for the gain G is to be maintained, the pumping source of the amplifier is capable of supplying the necessary pumping power. If this is not possible, then an error signal can be generated in advance.

This method can of course also be applied in such a manner that the maximum possible input signal power P_(in,max) is determined at predetermined time intervals or at predetermined times. If this value has decreased as a result of degradation to a minimum permissible value as set forth, for example, in a specification for the amplifier or the respective transmission path, then an error signal can be generated indicating that the amplifier or the transmission path no longer meets the specification, or that the amplifier or the transmission path may only be operated with lower optical powers than were originally established in the specification, or with a lower gain G if conditions permit.

According to one configuration of the invention, the functional dependence of the pumping current P_(pump) on the optical input signal power P_(in) and/or the optical output signal power P_(out) can additionally be determined as a function of the gain G, and stored if desired.

This makes it possible to perform the method in such a manner that, instead of a fixed value for the gain G, a maximum possible value of the gain G is determined, using the previously determined maximum possible value for the pumping power P_(pump,max) and the desired value for the input signal power P_(in), or the desired value for the optical output signal power P_(out), for this purpose.

The functional dependence of the pumping power on the input or output power and, if desired, on the gain, can of course be determined empirically for the specific amplifier or, as explained above, as an example for a given type of amplifier, the latter being possible or meaningful only if components of sufficiently similar characteristics are available.

The functional dependence of the pumping power on the above-mentioned parameters can of course be determined in the form of a value field or as a functional dependency and can optionally be stored.

If a direct proportionality in the form P_(pump)=β(G)·P_(in) is used as an approximation for the dependence of pumping power P_(pump) on the optical signal input power P_(in), where β(G) is a proportionality constant dependent on the gain G, then, using the proportionality P_(pump)=α·I_(pump), the maximum permissible value for the optical input signal power can be determined according to the relation P_(in,max)=P_(in,1)·I_(pump,max)/I_(pump,1), where the parameters with the index 1 are the respective corresponding parameters detected at the current time t₁.

In this way it is possible to specify a simple analytical relationship with the maximum possible input power P_(in,max) at a desired value of the gain G, whereby the former can be calculated without using numerical methods.

In place of the input signal power P_(in), it is of course also possible to use the optical output signal power P_(out) which results by multiplying the optical input power P_(in) and the gain G.

This method for monitoring an optical amplifier can of course also be used in the design and/or in an upgrade of an optical transmission path that contains at least one such optical amplifier.

Before increasing the optical power supplied to the transmission path at the input, the above-described method can first be used to determine the maximum input power at the input port of the amplifier that can be amplified by the amplifier (for a given gain G). Then the optical transmission path may be supplied at most an optical signal power that leads at the input and output of the amplifier to the maximum values for the input signal power P_(in,max) and for the output signal power P_(out,max) respectively, determined as a described above, taking into account the predetermined value for the gain G.

If the transmission path is a wavelength division multiplex transmission path, then, by determining the maximum permissible values for the input and output signal power P_(in,max) and P_(out,max), respectively, the maximum number of possible optical channels can be determined if their individual optical signal powers are added up.

In an upgrade of an existing wavelength division multiplex transmission path, a possible degradation that may have occurred in the meantime can be taken into account by the above-described method. The maximum possible value of the input signal power or the output signal power P_(in,max) or P_(out,max), respectively, is determined at the respective current point in time. The difference between the currently transmitted input or output signal power P_(in,1) or P_(out,1), respectively, and the respective possible maximum values P_(in,max) and P_(out,max) can then be ascertained as the power reserve ΔP_(in) or ΔP_(out), respectively. This power reserve must be greater than the additional power (at the input port or output port of the amplifier) that is to be transmitted for the channels that are to be added. It can naturally also be required that a given power reserve must remain as a security in order to compensate for future degradation of the amplifier.

The power to be transmitted via the optical transmission path can also be increased step-by-step starting from a current value for the transmitted optical power, until the maximum permissible input or output signal power P_(in,max) or P_(out,max) at the input or output port, respectively, of the amplifier has been reached. In the case of a wavelength division multiplex transmission path, additional channels can be added individually or in predetermined groups of 2, 3 or more channels. After each step the power reserve still remaining can be determined.

If the addition of a given number of optical channels to an existing wavelength division multiplex transmission system is planned and the currently determined power reserve is not sufficient, then the process of connecting the channels can either be completely prevented, or the number of channels to be added can be restricted such that the overall optical power to be added at the input port or the output port of the amplifier is less than the power reserve that is available.

This method can of course also be used for the case where several pumping sources are contained in one optical amplifier. Then the proportionality constant α applicable at any given point in time can be determined for each pumping source. From this the maximum “reserve” of the optical pumping power or the maximum optical pumping power can be determined in an analogous manner for each pumping source.

A device for monitoring an optical amplifier has, in addition to the objective characteristics of an ordinary optical amplifier, an evaluation and control unit that performs the above-described method, preferably using suitable software. The device can either be integrated into the amplifier itself or can be constructed as part of a higher-level device, for instance, a device for monitoring an optical transmission path or a management unit for managing a transmission path or a data transfer network. The device can of course also contain several pumping sources instead of a single pumping source, in which case the power of one or more pumping sources can be coupled into the optical path either in or against the signal transmission direction.

Additional embodiments follow from the subordinate claims.

The invention will be described in detail below with reference to figures of the drawing.

In the drawing:

FIG. 1 shows a schematic block diagram of an optical fiber amplifier for realizing the method of the invention, and

FIG. 2 shows a diagram of the dependence of the optical pumping power P_(pump) on the pumping current I_(pump) in the case of a degradation of the pumping source over time.

The fiber amplifier 1 shown in FIG. 1 has an input port 3 and output port 5, which are connected via an optical path 7. An optically active medium in the form of an amplification fiber 9, which can be embodied as an erbium-doped fiber, for example, is provided in optical path 7.

The optical input signal power P_(in) supplied to fiber amplifier 1 at input port 3 is detected by means of a coupler 11 and a detector unit 13. Coupler 11 diverts only a small part of the optical input signal power P_(in) away from optical path 7, and supplies this partial power to detector unit 13. Since the ratio k₁ of how much of the input signal power P_(in) of coupler 11 is diverted out of path 7 is fixed and known, detector unit 13 can correctly ascertain the value for the optical input power P_(in) and supply it to an evaluation and control unit 15.

Downstream of coupler 11 in the direction of signal transmission, an additional coupler 17 is provided in path 7, which couples the pumping power P_(pump) emitted at the output of an optical pumping source 19 into optical path 7 in the direction towards optical amplification medium 9. An amplification of the input signal with the input signal power P_(in) supplied to input port 3 of fiber amplifier 1 occurs by known mechanisms inside optical amplification medium 9. Part of the amplified output signal is coupled out by means of an additional coupler 21 arranged upstream of output port 5 in optical path 7 and is applied to an additional detector unit 23. Since the diversion ratio of coupler 21 is again fixed and known, detector unit 23 can ascertain the optical output power P_(out) of the optical signal emitted at output port 5. This value is likewise supplied to evaluation and control unit 15.

Evaluation and control unit 15 preferably controls pumping source 19 such that a predetermined value for the gain G is maintained, the gain G being defined as the ratio of the optical output signal power P_(out) and the optical input signal power P_(in).

Evaluation and control unit 15 is additionally aware of the relationship between the pumping power P_(pump) and the input signal power P_(in) to be amplified for the respective given value of gain G. This relationship can be stored, for example, as a functional dependency P_(pump)=f(G, P_(in)). Storage can be done in the form of a value field or in an analytical form.

Since the optical pumping power P_(pump) is approximately directly proportional to the pumping current I_(pump), which is specified to pumping source 19 by evaluation and control unit 15, the proportionality constant α(t₁) subject to degradation at the current time t₁ can be ascertained from the direct proportionality P_(pump)=α·I_(pump) where α indicates the proportionality constant, and the above-described connection between the pumping power P_(pump) and the gain G or the input signal power P_(in). For this purpose evaluation and control unit 15 uses a currently detected value for the optical input signal power P_(in,1), and the desired or predetermined value for the gain G and, from them it determines, with the relationship known to it, the pumping power P_(pump,1) that is necessary to amplify the input signal power P_(in,1) with a gain of G.

If this pumping power P_(pump,1) has been determined, then evaluation and control unit 15 can determine the currently valid proportionality constant α(t₁)=P_(pump,1)/I_(pump,1) from the above-mentioned proportionality relationship between the pumping power and the pumping current rate.

Additionally, devaluation and control unit 15 is aware of the value for the maximum possible pumping current I_(pump,max), which it can adjust at pumping source 19 in order not to destroy the electro-optical converter element of pumping source 19, such as a laser diode. Using the value for the maximum pumping current I_(pump,max) and the previously determined proportionality constant α(t₁), the value for the maximum possible optical pumping power P_(pump,max) can then be calculated as P_(pump,max)=α(t₁)·I_(pump,max), again using the proportionality relationship.

With this value for the maximum optical pumping power P_(pump,max), the maximum value for the input signal power P_(in) can be determined using the previously explained relationship P_(pump)=f(G, P_(in)) for the given gain G. The above-described functional dependency must of course be inverted for this purpose. If this relationship is stored as a value field, then this can be done by interpolation between adjacent values.

Thus evaluation and controlling unit 15 can determine in this manner how large the maximum optical input power P_(in) supplied at the input port 3 of fiber amplifier 1 can be in order to be able to still amplify it with the predetermined gain G without pumping source 19 having to be driven into an impermissible range. Since ordinary control units limit the value for the pumping current I_(pump) to the maximum value I_(pump,max), the gain G would fall below the desired predetermined value in case of an excessively high optical input signal power P_(in)>P_(in,max), i.e., the optical output signal power P_(out) would be smaller than the desired value. This would lead to an impairment of the transmission path.

Evaluation and control unit 15 can supply the ascertained value for the maximum input signal power P_(in,max) or the reserve ΔP_(in)=P_(in,max) P_(in,1) to a higher-level unit that decides, using these ascertained parameters, whether and, if appropriate, to what extent the input power P_(in) can be increased from the current value.

If the linearizing approximation P_(pump)=β(G)·P_(in) is used instead of the general functional dependency P_(pump)=f(G, P_(in)), then using the direct proportionality between the pumping power P_(pump) and pumping current I_(pump), it follows that

$P_{{i\; n},\max} = {P_{{i\; n},1}\frac{I_{{pump},\max}}{I_{{pump},1}}}$

Optical input power P_(in,1) and pumping current I_(pump,1) in this relationship are values that are detected at the respective current point in time and thus take into account a possible already existing degradation of the pumping source (with respect to the time t₀ that represents, for instance, the time of installation of the optical amplifier).

As already mentioned above, the degradation of pump source 19, as is evident from FIG. 2, leads over time (the relationships for times t₀, t₁. t₂ are illustrated here) to a reduction of the slope of the straight lines that represent the connection between the pumping power P_(pump) and the pumping current I_(pump). FIG. 2 also shows for the sake of example a point on the line for time t₁ with the pumping current I_(pump,1) and the corresponding pumping power P_(pump,1).

If the higher-level evaluation and control unit (not shown) is a unit for controlling a transmission path or a management unit for an entire transmission network, than such an evaluation and control unit can query the currently available maximum power reserve or the maximum possible input signal power from all optical amplifiers present in the transmission path. The optical input power at the beginning of the optical transmission path in question is then set by this evaluation and control unit such that the available power reserve or the maximum possible input signal power is not exceeded for any of the optical amplifiers.

If the transmission path is a wavelength division multiplex transmission path, then a performance increase by connecting additional channels may be necessary. By using the above explained method, it can then be checked before the connection of the additional channels whether an impairment of the currently transmitting channels will result because the maximum possible input signal power was exceeded at one of the optical amplifiers.

It can also be decided that either the addition of all channels will be abandoned or that merely a number of channels will be added that do not cause an exceeding of the maximum possible input signal power or an exceeding of the respective power reserve for any of the optical amplifiers.

It may be noted in closing that at every point where the input signal power P_(in) was used, this parameter could be replaced by the output signal power P_(out), since these two parameters are connected by way of the gain G. 

1. Method for monitoring an optical amplifier, in particular, an optical fiber amplifier, (a) which has an optical input port (3) and an optical output port (5), between which an optical path (7) extends, in which an optical amplification means (9) is arranged, (b) which has at least one pumping source (19), whose optical power (P_(pump)) is supplied via a coupling unit (11) to optical path (7), (c) wherein the optical input signal power (P_(in)) supplied to input port (3) of optical amplifier (1) and/or the optical output signal power (P_(out)) emitted at output port (5) of optical amplifier (1) is detected and (d) wherein the gain (G) of optical amplifier (1) is controlled or regulated to a predetermined nominal value, characterized in that (e) the optical pumping power (P_(pump)) is presumed to be approximately directly proportional to the electrical pumping current (I_(pump)) and wherein the time-variant proportionality constant subject to a degradation over time is designated with α(t), (f) the functional dependence of the optical pumping power (P_(pump)) on the optical input signal power (P_(in)) and/or the optical output signal power (P_(out)) is determined at least for the predetermined nominal value of the gain (G), (g) the current value (P_(pump,1)) for the optical pumping power is determined by means of this functional dependence as well as a currently detected value (P_(in,1)) for the optical input signal power or a currently detected value (P_(out,1)) for the optical output signal power, (h) with the thus-determined value (P_(pump,1)) for the current optical pumping power and a currently detected first value (I_(pump,1)) for the pumping current, the currently valid value for the proportionality constant (α(t₁)) is determined from the proportionality relationship, (i) the maximum possible value (P_(pump,max)) for the pumping power is determined from the maximum permissible value (I_(pump,max)) for the pumping current and from the currently valid value (α(t₁)) by means of the proportionality relationship, (j) using the maximum possible value (P_(pump,max)) for the pumping power, the maximum value (P_(in,max)) for the optical input signal power and/or the maximum value for the optical output signal power (P_(out,max)) is determined from the inverse functional dependence of the pumping current on the optical input signal power and/or the optical output signal power.
 2. Method according to claim 1, characterized in that the functional dependence of the optical pumping power (P_(pump)) is also determined as a function of the gain (G).
 3. Method according to claim 1 or 2, characterized in that the functional dependency of the optical pumping power (P_(pump)) is determined empirically for optical amplifier (1).
 4. Method according to one of the preceding claims, characterized in that the functional dependence of the optical pumping power (P_(pump)) is determined and stored as a value field.
 5. Method according to claim 1 or 2, characterized in that the functional dependence of the optical pumping power (P_(pump)) is determined as an analytical function.
 6. Method according to claim 5, characterized in that for the dependence of the pumping power (P_(pump)) on the optical input signal power (P_(in)), the relationship P_(pump)=β(G)·P_(in) is used, where β(G) is a proportionality constant depending on the gain (G), and in that the maximum permissible value for the optical input signal power is determined according to the relationship P_(in,max)=P_(in,1)·I_(pump,max)/I_(pump,1), using the proportionality P_(pump)=α·I_(pump).
 7. Method according to claim 6, characterized in that the optical input signal power (P_(in)) is replaced by the optical output signal power (P_(out)) by means of the relationship P_(out)=G·P_(in).
 8. Method for designing and or upgrading an optical transmission path having at least one optical amplifier (1) with the objective characteristics of claim 1, wherein input port (3) and output port (5) of the at least one optical amplifier (1) are connected to the transmission path by an optical transmission medium, characterized in that the optical transmission path is supplied only with an optical signal power that leads to a value for the input signal power (P_(in)) at input port (3) of amplifier (1) that is less than or equal to the maximum value (P_(in,max)) for the input signal power, or that leads to a value for the output signal power (P_(out)) at output port (5) of amplifier (1) that is less than or equal to the maximum value (P_(out,max)) for the output signal power.
 9. Method according to claim 8, characterized in that the optical transmission path is a wavelength division multiplex transmission path and in that, when one or more optical channels are to be added to the wavelength division multiplex signal to be transmitted, the power reserve for the optical input signal power ΔP_(in)=P_(in,max) P_(in,1) or the power reserve for the optical output signal power ΔP_(out)=P_(out,max) P_(out,1) at the at least one amplifier (1) is first determined.
 10. Method according to claim 9, characterized in that the one or more additional channels to be added are added only if the power that is generated at input port (3) or output part (5) of amplifier (1) by the one or more channels to be added is less than the respective power reserve (ΔP_(in); ΔP_(out)).
 11. Method according to claim 9, characterized in that only a number of channels that generate an optical power at input port (3) or output port (5) of amplifier (1) that is less than the respective power reserve are added.
 12. Device for monitoring an optical amplifier (a) which has an optical input port (3) and an optical output port (5), between which an optical path (7) extends, in which an optical amplification means (9) is arranged, (b) which has at least one pumping source (19), whose optical pumping power (P_(pump)) is supplied via a coupling unit (17) to the optical path, (c) which has means (11, 13) for detecting the optical input signal power (P_(in)) supplied to input port (3) and/or which has means (21, 23) for detecting the optical output signal power (P_(out)) supplied to output port (5) and (d) which has means (15) for controlling or regulating the optical gain (G) of the optical amplifier to a predetermined nominal value, characterized in that (e) the device comprises an evaluation and control unit (15), to which thus information the detected input signal power (P_(in)) and/or the detected output signal power (P_(out)) is supplied and which is configured such that it performs the method according to one of claims 1-7.
 13. Device according to claim 12, characterized in that it transfers the maximum value (P_(in,max)) for the optical input signal power and/or the maximum value (P_(out,max)) for the optical output signal power and/or the power reserve for the optical input signal power (ΔP_(in)=P_(in,max) P_(in,1)) and/or the power reserve for the optical output signal power (ΔP_(out)=P_(out,max) P_(out,1)) to a higher level or equal level evaluation and/or control unit. 